hydrogen chloride sparging crystallization of the chloride
TRANSCRIPT
iRIi S930
Bureau of Mines Report of Investigations/1985
Hydrogen Chloride Sparging Crystallization of the Chloride Salts of Cobalt, Manganese, and Nickel
By D. E. Shanks and E. G. Noble
UNITED STATES DEPARTMENT OF THE INTERIOR
I
j + I
Report of Investigations 8930
Hydrogen Chloride Sparging Crystallization of the Chloride Salts of Cobalt, Manganese, and Nickel
By D. E. Shanks and E. G. Noble
UNITED STATES DEPARTMENT OF THE INTERIOR Donald Paul Hodel, Secretary
BUREAU OF MINES Robert C. Horton, Director
I' ,I !'
I -,
Library of CpngressCataloging in Publication Data:
Shanks, D. E. (Donald E.) Hydrogen chloride sparging crystallization of the chloride salts of
cobalt, manganese, and nickel.
(Report of investigations; 8930)
Bibliography: p.13·14.
Supt. of Docs. no.: I 28.23:8930.
1. Chlorides. 2. Crystallization. 3. Hydrochloric acid. I. Noble, E. G. (Elaine G.)~ II. Title. III. Series: Report of investigations (United States. Bureau of Mines) ; 8930.
TN23.U43 [TP245.C5] 622s (669',028'3] 84·600270
CONTENTS
Abstract •...••.•...........•..........•.•......•...........•.• 8................ 1 Introduction •.•.........••.........•••...••............•....•.•.........•...•. " 2 Materials and equipment........................................................ 2 Procedure. • • . • . . • • . . • • . • . . • . • . . . • • • . • . • • . • . • . • • . . • . • . . . . . . • . • . . • . . . . . • . . . . • . . . • 4 Precision and accuracy......................................................... 5 Results and discussion •....•...•..•..•••..•..•...•......... 0.......... .... ..... 6
Cobalt chloride.............................................................. 7 Manganese chloride........................................................... 9 Nickel chloride •..•••••. G ••••••••••••••••••••••••••••••••••••••••••••• "...... 10
Summary and conclusions........................................................ 13 Ref erences ••••••••.••••• ,. . • • • • • • • • • • • • • • • . • • • • . • . • • • . • • . • • • • . • • • • • • • • • • • • • • . . • • 13 Appendix. • • • • • • • • • • • • • • • • • • . • • • • • • • • • • • • • • • • • • • • • . • . • . • • • • • • • • • • . . • • • • • • . . . . . • • 15
ILLUSTRATIONS
1. Sparging apparatus ••••••••••••••••••••••••••••••••••••••••••••••••••••••• 2. Solubility of CoCl 2 as functions of RCI concentration and temperature in
3. 4. 5. 6.
7. 8. 9.
10.
11. 12. 13.
A-I. A-2. A-3. A-4. A-5. A-6. A-7. A-8. A-9.
the s ys tem CoC1 2 -HCI-H2 O .•••.....•.•...............................•...• Tieline plot of the data for the CoCI 2-HCI-H20 system at 20° C ••••••••••• Tieline plot of the data for the CoCI 2-RCI-H20 system at 40° c ••••••••.•• Tieline plot of the data for the CoCI 2-RCI-H20 system at 60° C ••••••••••• Solubility of MnCl 2 as functions of RCI concentration and temperature in the system MnC12-HCl-H20 •••••••••••••••••••••••••• G •••••••••••••••••••••
Tieline plot of the data for the MnC1 2-HCI-H20 system at 20° C ••••••••••• Tieline plot of the data for the MnCI2-HCI-H20 system at 40° C ••••••••••• Tieline plot of the data for the MnCI 2-HCI-R20 system at 60° C ••••••••••• Solubility of NiCl 2 as functions of RCI concentration and temperature in the system NiC12-HCI-R20 ••••••••••••••••••••••••••••••••••••••••••••••••
Tieline plot of the data for the NiC1 2-RCl-R20 system at 20° C ••••••••••• Tieline plot of the data for the NiC1 2-HCl-HzO system at 40° C ••••••••••• Tieline plot of the data for the NiCI2-HCI-H20 system at 60° C •••••••••••
TABLES
CoCI z-HCI-H2 ° system at 20° C ••••••••••••••••••••••••••••••••••••• e ••••••
CoCI 2-RCI-R20 system at 40° C •••••••••••••••••••••••••••••••••••••••••••• COCI2-RCI-H20 syst.em at 60° C ••••••••••••••••••••••••••••••• o ••• " ••••••••
MnCI2-RCI-H20 system at 20° C •••••••••••••••••••••••••••••••••••••••••••• MnCI2-RCI-R20 system at 40° C •••••••••••••••••••••••••••••••••••••••••••• MnCI2-HCI-H20 system at 60° C •••••••••••••••••••••••••••••••••••••••••••• NiCI2-RCI-H20 system at 20° C ••• 0 ••••••••••••••••••••••••••••••••••••••••
NiClz-HCI-R20 system at 40° c ......••.....••..•••.................•...... NiCI2-HCI-H20 system at 60° C ••••••••••••••••••••••••••••••••••••• 8 ••••••
3
7 7 8 8
9 9
10 10
10 10 12 12
15 15 16 16 17 17 18 18 19
UNIT OF MEASURE ABBREVIATIONS USED IN THIS REPORT
DC degree Celsius mL milliliter
cm3/min cubic centimeter mL/min milliliter per minute per minute
mm millimeter g gram
pct weight-percent h hour
psig pound (force) per square hp horsepower inch, gauge
in inch rpm revolution per minute
L liter sp gr specific gravity
m meter
i.
II
I
HYDROGEN CHLORIDE SPARGING CRYSTALLIZATION OF THE CHLORIDE SALTS OF COBALT, MANGANESE, AND NICKEL
By D. E. Shanks 1 and E. G. Noble 2
ABSTRACT
The Bureau of Mines investigated the effects of HCI concentration and solution temperature on the solubility and crystal form of the chlorides of Co, Mn, and Ni when sparged with HCI gas at temperatures of 20°, 40°, and 60° C. Increasing HCI concentration in solution caused the chlorides of Co, Mn, and Ni to crystallize (salt out) because of the common ion effect. The salting-out crystallization was most effective for NiCI 2 , which had a solubility of 0.7 pct at 20° C and maximum HCI concentration. COCl2 salted out to a minimum solubility of 9.4 pct at 20° C and 22 pct HCI concentration and increased in solubility at greater HCI concentrations because of the formation of chloride complexes. MnCl2 was intermediate in behavior. The effect of temperature on solubility was greatest for CoCl2 and least for NiCI 2 , 15 and 7 pct change, respectively, over the temperature range of 20° to 60° C.
The salted-out chlorides of cobalt and nickel formed the hexahydrates and those of manganese formed the tetrahydrate in saturated metal chloride solutions at 20° C and low concentrations of HCI. Increasing the temperature or the HCI concentration caused a 108s in waters of hydration. At 60° C, the salted-out crystals of NiCl2 formed the tetrahydrate in HCI concentrations up to 18 pct and the dihydrate at higher concentrations, while cobalt and manganese chlorides formed the dihydrates, even in water.
r
Research chemist. 2Chemist. Reno Research Center, Bureau of Mines, Reno, NV.
2
INTRODUCTION
Stricter control of effluents and declining are grades have caused an increase in interest in hydrometallurgical processing. Much of the new technology in hydrometallurgical processing makes use of acid chloride systems. Chloride processing for recovery of Mg, K, and Li from seawater and brines has been practiced for many years. Most of the chlorides are highly soluble in aqueous solution, but many can be removed from solution as a consequence of dramatic decreases in solubility resulting from the common ion effect caused by increasing the chloride ion activity.
Practical use of the sensitivity of chloride salt solubility to changes in HCI concentration can significantly improve the efficiency of chloride hydrometallurgical processes. For example, in the HCI process for producing alumina from clay, a pure, crystalline AlC1 3 '6H20 product is recovered from contaminated pregnant liquors by the decrease in solubility caused by addition of RCI gas.
The goal of this study is to stimulate interest in and expand the data base for sparging crystallization of chlorides of metals having strategic or critical economic importance by investigating the effects of HCl gas concentration and solution temperature on the solubility, chemical composition, and physical characteristics of the salted-out metal chloride crystals.
Limited data are available on the solubility and solid phases formed during the salting-out crystallization of chloride salts with HCl. The data were gathered in long-term equilibrium tests
using closed containers and predetermined amounts of constituents. Publications published prior to 1956-57 were summarized in Linke-Seidell (1).3 Only four references, the OoCl 2-HCI-H 20 system at 0° C by Engel (2), the CoC1 2-HCI-H 20 system at 25° C by-Bassett and Croucher (3), the CoC12-HCI-H20 and NiC12-HCl-H20 systems at 0° C by Foote (4), and the NiC12-RCl-H20 systems at 20° C and 80° C by Babaeva and Archakova (2), are cited. A recent paper by Balarew, Spassow, and Simeonawa (6) covered the solubilities and crystal~ydrate salts of the NiC1 2-RCl-H20 system at 25° C and the MnC1 2-RCl-H20 system at 25°, 40°, and 50° C. Salting-out crystallization occurred in all three systems; GoC12 was initially the least soluble and MnC1 2 was the most soluble. ~rhis relationship changed at high HCI concentrations, where COC12 formed chloride complexes and became considerably more soluble, while NiCl2 continued to salt out and became much less soluble. There was an increase in solubility and a decrease in hydration with increasing temperature.
Earlier sparging crystallization work by the Bureau of Mines to purify AlG13 (7) showed that the solubility curves matched those obtained by the equilibrium method used by Malquori (8), Seidell and Fischer (9), and Brown, Daut, Mrazek, and Gokcen (10). If this relationship holds for other-chloride salts, the data base on chloride salt behavior in aqueous HCI could be rapidly and easily expanded by carrying out HCl sparging experiments. Data collected would also be more relevant to metallurgical applications than data collected from long-term equilibration tests because of the more realistic time span.
MATERIALS AND EQUIPMENT
Sparging was performed in a jacketed borosilicate glass action kettle with a four-port with standard taper joints Temperature was controlled by erated circulator bath (-15°
3-L waterresin relid fitted (fig. 1). a ref rig
to 100° C,
±O.02° G control accuracy) connected by rubber tubing to the sparging tank water
3Underlined numbers in parentheses refer to items in the list of references preceding the appendix.
r
HCI
Carrier gas
HCI-carrier gas mixture
Mixing vessel
Gas delivery
Flowmeter tube
HCI Corrier tank gos
tonk
Sparging reactor
Heating -and cooling
water lines
Circulator
Water jacket
Stirrer
FIGURE 1. - Sparging apparatus.
jacket. Temperature mercury thermometers increments.
was monitored with marked in 0.1 0 C
Sparging and carrier gases were delivered through pressure regulators and flowmeters to a mixing chamber and through a glass sparging tube located just above the propeller located in the sparger vessel. The HCI gas was controlled by a regulator containing a check valve to prevent the return flow of gas into the tank. The HCI and carrier gas flows were measured with rotameters containing glass floats designed to measure flows of 100 to 2,440 cm3/min and 20 to 386 cm3/min, respectively. The mixing chamber consisted of a l-L filter flask filled with glass wool. The contents of the sparger vessel were mixed with a three-bladed, steel-reinforced, linear polyethylene stirrer (18-in length, 1/4-in shaft diameter, l-3/4-in propeller
3
diameter, and 45° pitch) connected by a flexible shaft assembly to a variablespeed 1/40-hp electric motor capable of 0- to 6,000-rpm armature shaft speed. A Teflon4 standard taper inlet adapter with slightly oversized 1/4-in hole was used as a centering device and bushing for the stirrer. The bushing was not made gas tight because the carrier gas had to be removed from the system.
Each experiment started with a saturated solution of the metal chloride. The solutions were prepared by heating 1 to 2 L of water to slightly greater than the desired temperature, slowly stirring in an excess of the chloride (Baker Analyzed Reagent grade) until excess solids remained for at least 24 h after the last addition, and cooling to the desired temperature. Reagents used to make saturated solutions included crystals of manganous chloride, MnC12"4H20; cobalt chloride, CoC12·6H20j and nickelous chloride, NiCI2·6H20. The spargi.ng gas was Matheson technical-grade hydrogen chloride, >99 pct HCI. Reagents used for analytical purposes were standardized 0.1N HCI and carbonate-free NaOH, and ACS reagent-grade silver nitrate.
Chloride crystals were filtered through 3-L coarse-porosity fritted glass Buchner funnels. Crystal-free samples of solution were removed from the crystallizer through l2-mm-diam coarse-porosity fritted glass cylindrical gas dispersion tubes. Hydrogen and total chloride ion concentrations were determined with an automatic titrating apparatus with motordriven burette and magnetic stirrer, utilizing a standard pH electrode for hydrogen ion tit rations and a chloride ionspecific electrode for chloride titrations. A sleeve-type double-junction calomel internal reference electrode with salt bridge filling solution of sodium acetate-sodium nitrate in water was used.
4Reference to specific not imply endorsement by Mines.
products does the Bureau of
I I,
Ii i,
I:,: "
Ii '.'
4
Cobalt, manganese, and nickel concentrations were determined by atomic absorption spectroscopy and by chloride titrations after allowing for the chloride contribution from HCI. The cation concentrations were confirmed by a
gravimetric technique in which measured volumes of the hydrated chlorides were dried in air at 200 0 C for at least 12 h and weighed to determine anhydrous chloride content.
PROCEDURE
Saturated chloride solutions were maintained at temperatures of 20°, 40°, or 60° C, and sparged with a mixture of HCI and carrier gases until saturated with HCI. The HCI passing through the Matheson 603 flow meter was adjusted to a flow rate of 36 units in a ISO-unit scale, which equated to a flow rate of 850 mL/ min. The carrier gas, air or nitrogen, was regulated at 10 psig and delivered at 100 units on the Matheson 602 flow meter, which corresponded to a flow rate of 200 mL/min. The carrier gas was added because experience with AlC1 3 crystallization showed that larger, purer crystals were produced, fewer problems were encountered with sparger tip plugging, and solution aspiration was eliminated. Stirrer speed was not measured, but was continuously adjusted to the minimum speed that would keep the solids in suspension. The 850-mL/min HCI flow rate was the fastest flow that could be utilized without exceeding the cooling capacity of the circulator (HC1 hydration 1s very exothermic) and gave a reasonable sampling frequency. The chloride salt slurry was sampled prior to sparging and then hourly until the conclusion of the experiment. Approximately 5-mL samples were drawn from the slurry through a fritted glass gas dispersion tube to insure that no solids were removed. The solution was added to a volumetric flask approximately half full of a weighed amount of water. The volumetric flask was weighed after the sample was added and again after the flask was filled to the 100-mL mark. This procedure minimized loss of HCI and allowed for calculation of the weight of the sample and density of the diluted sample. The specific gravity was determined directly on the 20° C samples with a Mettler-Paar DMA 35 density meter. For measurement of specific gravity at temperatures outside the 10° to 30° C range of the instrument,
a 5-mL sample of the solutions was weighed. Glassware for handling undiluted samples was heated to greater than operating temperature to prevent precipitation. An approximately 5-mL slurry sample was collected with a ladle. The solids were partially dried by blotting on glass fiber filter paper, weighed, dissolved in water, and made up to volume in a 100-mL volumetric flask.
The three samples were used to determine HCI concentration in solutions and wet residues, metal chloride concentration in solutions and wet residues, and solution densities. To improve sampling precision, 1-mL aliquots were withdrawn from the volumetric flasks and weighed, and the weight was divided by the density of the solution. The HCI concentration was determined by diluting a l-mL aliquot to 50 mL with water and titrating with standardized O.lOOON NaOH. The automatic titrator determine~the end point as the inflection point of the titration curve and printed out the volume of titrant consumed in reaching the endpoint. HCl concentration was calculated from the equation
where Rl = concentration of HCI, pet,
E 1 = NaOH volume, mL,
Cl = 364.6 = meq wt HCI x volumetric flask volume x conversion factor wt fraction to wt pet,
Cz = 0.1000 = NaOH ~,
C3 = volume of aliquot titrated, mL,
and C4 = weight of sample, g.
Metal chloride concentration was determined by titrating a I-mL aliquot with standardized O.lOON silver nitrate (AgN03) and a chloride-specific ion electrode. The endpoint volume was converted to metal chloride concentration by the formula
where R2 = metal chloride concentration, pet,
E2 = AgN03 volume, roL,
C5 = 649.2 for CoC12, 629.2 for MnCI2, and 648.1 for NiCI2,
C6 = AgN0 3 concentration, N,
C7 = volume of aliquot titrated with AgN03 , mL,
R3 = correction for chloride contributed by HCI = EI x C2/C3,
EI = NaOH volume, roL,
and
C2 = 0.1000,
C3 = volume of aliquot titrated with NaOH, roL,
C4 = weight of sample, g.
5
Metal chloride was checked by a gravimetric technique in which 25-mL aliquots were dried under heat lamps, heated to 2000 C in a muffle furnace, cooled in a vacuum desiccator, and weighed as the anhydrous chloride. Atomic absorption spectroscopy on low-metal-chloride concentrations was used to supplement the gravimetric results.
The experiments were terminated when HCI sparging ceased to influence the HCl and chloride salt concentrations. The slurries were filtered through fritted glass to separate solids from solution. The solids were examined microscopically to determine their morphology. The wetresidue and solution compositions were plotted on triangular coordinate paper, and tielines were constructed to determine crystal composition by SchreinemakersT wet-residue method (11).
PRECISION AND ACCURACY
The usual problems of evaluating the analytical precision and accuracy of the measured parameters were present. A potentially more serious accuracy problem inherent in this research was chemical nonequilibrium. In conventional studies, premeasured quantities of reagents are shaken in closed containers for long periods of time, while maintaining constant temperature. Readings are taken until the systems are in equilibrium. With the sparging technique, concentrations of reagents are constantly changing and HCI can easily escape. Comparison of equilibrium data from previous and current studies indicated that the reaction kinetics are very fast and HCI is not easily lost from solution. This was confimed by measurements made after sparged slurries were allowed to stand overnight without additional sparging. Metal chloride and HCI concentrations changed by
less than 0.1 pet. Simultaneous bottle tests of 2 weeks' duration gave almost identical results.
The titration of chlorides and HCI represented the major precision-limiting step in the solubility determinations. In several hundred titrations of 0.1000N HCI with AgN03 and NaOH to determine chloride and HCI concentrations, average values of 0.0991 iO.OOllN were indicated for AgN03 and NaOH concentrations of the titrants. This represents an absolute variation of ±1.1 pet for each titration, and since the contribution of chloride from HCI must be subtracted from the total chloride concentration, the two errors are additive and give up to 2.2 pet error. The variation of data points from the smoothed curves was up to ±0.1 pct (a 1.0-pct error on an absolute basis for a sample containing 10 pet HCI and 10 pct
6
metal chloride) and was the other primary source of error. Some of the ancillary measurements had larger relative errors, but had no bearing on the precision and accuracy of the solubility work. For instance, the estimated precision of HCI flow rate measurements was pet, but experience gained from AlC13·6H20 crystallization showed that HCI flow rate was not an important parameter at flow rates less than 1,300 mL/min. Specific gravity measurements at 40° and 60° C showed considerable scatter and varied as much as ±3 pct; therefore, the values reported for specific gravity in tables A-I to A-9 (appendix) were determined from smoothed curves. Other sources of error were minor. Originally, pipetting errors of up to 2 pct were noted, but this source
of error was decreased by at least an order of magnitude by weighing the samples and dividing by the density to get correspondingly accurate volumes. The volumetric flasks were certified to contain 100±0.OS mL of solution, which calculates to a maximum error of O.OS pct. Temperatures were measured with thermometers marked in 0.1° C increments and estimable to 0.02° C. Observed temperature variations were within 0.05° C. Each thermometer was calibrated against a set of National Bureau of Standards (NBS) certified thermometers and read within ±0.1° C of the certified temperature in the 20° to 60° C range. Temperature variations of 0.1° C would lead to a maximum metal chloride concentration error of 0.1 pet.
RESULTS AND DISCUSSION
The most important common properties of the three systems were the rapid approach to equilibrium and the maintenance of equilibrium conditions in the HCI environment created by HCl sparging. The kinetics were not studied per se, but rapid attainment of equilibrium was inferred from the close agreement between this study, earlier research by others in which equilibrium was attained, and separate equilibrium studies conducted in this research.
The three compounds evaluated were very soluble in water. Their solubilities were highly temperature dependent over the temperature range investigated and ranged from 34.6 to 52.1 pet. Increasing the HCl concentration by sparging caused a decrease in solubilities of the three metal chlorides due to the common ion effect. The decrease in solubility was mos t pronounced for NiC12' A minimU111 of 0.7 pct NiClz at 37.1 pct HCI concentration was obtained. This contrasts to the minimum solubilities of 9.4 pct for CoCl2 and 11.3 pct for MnC12 at HCI concentrations of 22.0 and 34.0 pct HCI, respectively. The solubility minimums for both COCl2 and MnCl2 occurred before the solutions were saturated with HCI. This behavior is due to chloride complexation at
high HCI concentration and results in increased solubilities of lS.l pct CoCl 2 and 11.9 pct MnCl 2 in solutions saturated with HC!.
The slopes of the solubility curves for Co, Mn, and Ni chlorides were almost identical for the initial salting-out portions of the diagrams (figs. 2, 6, and 10). Solubility differences for solutions up to about 20 pct HCI concentration were due to the differences in aqueous solubility at a given temperature. At HCI concentrations greater than 20 pct, solubility differences were due to differences in chloride complex formation. NiCl z does not form strong chlorocomplexes and its solubility decreases when the HCl concentration is increased, whereas CoCl 2 forms strong chlorocomplexes and increases in salubility at greater HCI concentrations. MnC12 is intermediate in both complexing response and solubili ty.
Increasing both temperature and HC! concentration decreases the hydration state of the salted-out crystals. Cobalt and nickel chlorides were in equilibrium with hexahydrate salts, and MnC12 was in equilibrium with tetrahydrate salt at 20° C in water. These chlorides were in
equilibrium with dihydrate salts in concentrated HCI at 60° C. The dehydration to dihydrate crystals was not desirable because the dihydrates formed very small, needlelike crystals that were difficult to filter.
Data for the three systems at the temperature ranges investigated are summarized in tables A-I to A-9. The information in each table represents a composite of two or three experiments and is discussed in the following sections. From these tabulations, the solubility curves in figures 2, 6, and 10 and the tieline diagrams in figures 3-5, 7-9, and 11-13 were plotted.
COBALT CHLORIDE
CoCI Z concentration and specific gravity as functions of HCI concentration at 20° C are tabulated in table A-I and plotted in figures 2 and 3. The CoCl 2 solubility curve in figure 2 is almost linear with a slope of -1.4 pct CoClz per percent HCl up to an HCI concentration of 14 pet. There is a solubility minimum of 9.4 pct at 21 pct HCI, and a rapid increase in solubility to 16.5 pct CoClz at 24 pct HCI. This is an invariant point where solid CoC12'6H20 and probably CoCl z ' 2HzO are in equilibrium with the solution, as evidenced by the change in the intersection of tieline plots in figure 3 and the change in crystal habit from large, red basal tablets to very small, blue-violet, elongated prisms. The tieline data are not clear on the species produced at the break from the hexahydrate. The lower hydrate could be a tetrahydrate or dihydrate, or it could be of the form HCI'CoCI2'7HzO; previously published data (1) show a hexahydrate to dihydrate transition. A secondary minimum of 15.8 pet CoCl2 at 27 pct HCI is followed by a solubility increase to 18.1 pct COCl z at HCI saturation, 31.9 pct. Saturation of HCI should be slightly lower at the location of this experiment, owing to the reduced average ambient atmospheric pressure of 642 rom of Hg at an elevation of 1,402 m above mean sea
50
N (.)
KEY " 20· C a 40· C 6 60· C
<3 25
20
15
10 -
5 0 5 10
FIGURE 2. - Solubi I ity of CoCI 2 as functions of HCI concentration and temperature in the system CoCI 2-I-ICI-H 20.
/-/\ !
1\ /\ KEY /\
c 20° C aqueous solubility
• Wet residue
• Theoretical intercept
\
\
FIGURE 3. - Tieline plot of the data for the CoCI 2-HCI-H 20 system at 20 0 C.
7
level, as compared with most sea level locations with an average ambient atmospheric pressure of 760 rom Hg.
No previously published values are available for the CoC1 2-HCl-H 20 system at 20° C, except the saturation point in water, which is reported as 34.6 pct
8
by Linke-Seidell (1). This is close to the 33.9-pct solubility determined in this study. The CoCI 2-HCI-H20 system was studied at 0° C (4) and at 25° C (3). The CoCl 2 solubility curve in this research is similar in shape to the curves of Foote (4) and Bassett and Croucher (3); the point of solid-phase transition from the hexyhydrate to the dihydrate is intermediate in position but closer to the 25° C curve. Linke-Seidell (1) included 0° C data from Engel (2) which are considerably different from -Bureau and Foote's research. This discrepancy is probably due to typographic errors either in Engel's original publication or in Linke-Seidell, for when Engel's data are multiplied by 10, they match Foote's data.
CoCl 2 concentration and specific gravity as functions of HCI concentration at 40° C are tabulated in table A-2 and plotted in figures 2 and 4. The CoCl2 solubility curve for 40° C is almost parallel to the 20° C curve and has the same configuration. The solubility of CoCl2 in water was 40.9 pct as compared to 41.0 pct in Linke-Seidell. The initial slope was -1.3 pct CoCl 2 per percent HCI. There was a distinct break in the 40° C curve in figure 2 at a solution composition of 14.3 pct HCI and 27.8 pct COCI2_ This coincided with a jump in the tieline data in figure 4 from a H20-CoCI 2 baseline intercept indicating hexahydrate to one indicating tetrahydrate. This coincided with a distinct change in crystal habit from large, red basal tablets to very small, blue-violet elongated prisms.
° 40· C aqueous solubility • Wet residue • Theoretical Intercept
\
FIGURE 4. - Tiel ine plot of the data for the CoCI 2-HCI.H 20 system at 40 0 C.
A further transition from the tetrahydrate to the dihydrate is indicated in figure 4 at a solution composition of 17.7 pct HCI and 23.8 pct CoCI2, but no corresponding invariant point is apparent in figure 2. Since the tieline data are not as accurate as the solution composition data, additional experimentation is needed to prove or disprove the existence of a CoC1 2·4H20 phase. The aqueous solubility data in Linke-Seidell show a narrow temperature region from 49° to 58° C in which a CoCl204H20 solid phase can exist, but other researchers do not support the formation of this phase (3-4, 12). Minimum COCl2 solubility occurred at 23.9 pet HCI and was 19.6 pct CoCI 2• A slight increase to 21.6 pct CoCl 2 solubility was observed at HCI saturation of 28.4 pct.
Cobalt chloride concentration and specific gravity as functions of HCI concentration at 60° C are tabulated in table A-3 and plotted in figures 2 and 5. The solubility curve in figure 2 is parallel to the 20° and 40° C curves, starts at an aqueous solubility of 48.3 pet CoCI 2, and decreases in CoCl 2 concentration at a slope of -1.3 pet CoCl z per percent HCI to a minimum at 23.0 pet HCI and 24.0 pct CoCI2' A CoCl2 concentration of 24.2 pet is obtained at HCI saturation of 24.4 pet. Data in Linke-Seidell show 48.4 pct CoCl2 solubility at 60° C and a solid phase of CoCI 2"2H20. Blue, elongated prisms were noted throughout the experiment. There were no breaks in the solubility curve, and the tieline data in figure 5 indicate a CoC12'2H20 composition. When data from the above
KEY t'. 60· C aqueous solubility • Wet residue
• Theoretical Intercept
\I
FIGURE 5 •• Tiel ine plot of the data for the CoCI 2-HCI.H 20 system at 60° C.
experiments at 20°, 40°, and 60° C and for 0° and 25° C from Linke-Seidell are plotted as a family of curves, the curves are approximately parallel, with corresponding points, such as minimums and invariants, lying above and to the left as the temperature is increased.
MANGANESE CHLORIDE
MnCl 2 concentration and specific gravity as functions of HCI concentration at 20° C are tabulated in table A-4 and plotted in figures 6 and 7. The 20° C curve in figure 6 indicates a solubility ranging from saturation at 42.6 pct MnC1 2 in water (compared to 42.5 pct in LinkeSeidell), to 15.2 pet MnCl2 at 23.0 pet HCI, to an invariant point at 16.3 pct MnCI 2-25.2 pct HCI concentration, to a minimum of 11.3 pet MnCl 2 at 33.7 pet HCI, and to 11.9 pet at HCI saturation of 35.0 pet. The steepest portion of the curve has a slope of -1.4 pet MnCl2 per percent HCI. The sharp break in the curve is an invariant point marking the transition from MnC12°4H20 to MnCI2·2H20. This conclusion is supported by the tielines in figure 7 and by the observation of a change from fairly large, pink, basal tablets to very fine, pink elongated prisms. The solubility and solid phase data agree with those from equilibrium tests made by Balarew (6) at 25° C that show almost parallel, but slightly higher, curves with an invariant point at 1S.3 pet MnCI 2-22.7 pct HCI, and wet residue tieline plots indicating the transition from MnClzo4H20 to MnCI2·2H20. The aqueous solubility information in LinkeSeidell shows a solid-phase transition from tetrahydrate to anhydrous at 60° C, whereas thermal decomposition data in Colton and Canterford (12) indicate the follOWing transitions: --
50° C 1350 C MnC12'4H20 + MnC12'2H20 + MnC1 2 oH2 0 •
MnCl 2 concentration and specific gravity as functions of HCI concentration at 40° C are tabulated in table A-5 and plotted in figures 6 and S. MnCl 2 solubility was 46.7 pet compared to 47.0 pct in Linke-Seidell. Crystallization by
9
sparging with HCI decreased the solubility of MnCl 2 to a minimum of 14.4 pct at HCI saturation of 30.9 pct. The initial slope of -1.4 pct MnC1 2 per percent HCI was parallel to the 20° and 60° C curves. There was a possible small inflection point at 2S.2 pet MnCI 2-IS.S pct HCI that marked the transition from MnCl 2 '4H20 to MnCl2'2H20 in the salted-out crystals. Tieline data in figure S show the breakpoint at the same place. Visual
55
KEY
o 20° C
° 40° C " 60° C L'lI Linke-Seidel
solubility dotum
't 35 a.
N (.)
i 30
25
20
15:
lol~_.':-I __ ..':-1 --,,=1 --=",1 c--_-:-'-I=--_='I-,--_-::'I o 5 10 15 20 25 30 35
Hel, pef
FIGURE 6. - SolubIlity of MnCI 2 as functions of HCI concentration and temperature in the system MnCI 2-HCI-H 20.
KEY \
u 20" C aqueous solubility \
• Wet residue t <:J. ~
• Theorellcal intercept
~ ...
\
FIGURE 7. - Tieline plot of the data for the MnCI 2-HCI.H 20 system at 20° C.
10
° 40° C aqueous solubility • Wet residue • Theoretical intercept
\ \i \I
FIGURE 8 •• Tieline prot of the data for the MnCI 2-HCI-H 20 system at 40° C.
observation also showed a change from large basal tablets to very fine elongated prisms. This experiment was compared with conventional equilibrium experimentation at 40° C by Balarew (~). The agreement .in the two sets of data was within 0.5 pct. Balarew found that the transition from tetrahydrate to dihydrate was at 29.1 pct MnC12-16.2 pct HCl. HCl saturation was determined to be 30.9 pct, compared with 25.3 pct by Balarew.
MnCl 2 concentration and specific gravity as functions of HCl concentration at 60° C are tabulated in table A-6 and plotted in figures 6 and 9. The 60° C curve starts with aqueous solubility of 52.1 pct (same value as in LinkeSeidell), The 60° C curve has no breaks and slopes at -1.4 pct MnCl 2 per percent HCI, The tieline data in figure 9 show a single convergence at a composition of MnC12'2H20. Microscopic examination of the crystals showed very small elongated prisms, which were expected because decomposition data in Colton and Canterford indicated that the solid phase at 60° C was dihydrate. Linke-Seidell found anhydrous MnC1 2 at 60° C and a transition to dihydrate at 146° C; these conditions are not likely, The minimum MnCl z solubility occurred at MnCl2 concentration of 19.5 pct and HCI saturation of 25.5 pet.
NICKEL CHLORIDE
Data for the system N1CI 2-HCI-HzO at 20° C were tabulated in table A-7 and plotted in figures 10 and 11. Solubility of NiCl 2 ranged from 37.7 pet in water to
£; 60· C aqueous solubilily • Wei residue
• Theoretical inlercept
\
FIGURE 9. - Tiefine plot of the data for the MnCI 2 -HCI·H 20 system at 60° C.
45
30
15
KEY o 20· C o 40· C
l> 60° C
III Linke-Seidel solubility datum
• Equilibrium datum
Hel, pet
FIGURE 10. - Solubility of NiCI 2 as functions ofHCr concentration and temperature in the system NiCI 2-HCI.H 20.
o 20· C aqueous solubility ~ • Wei residue • Theoretico I intercept
\
FIGURE 11.· Tieline plot of the data for the NiCI 2-HCI.H 20 system at 20° C.
0.7 pct in 37.1 pct HCI and 1.1 pct at HCI saturation of 37.5 pct. The slope of the curve is -1.3 pct NiCl z per percent HCI and is approximately parallel to that of the 40° and 60° C curves. Breakpoints in the solubility curve occur at NiCl 2 and HCI concentrations of 35.8 pct and 3.6 pct, 8.2 pct and 25.1 pct, and 1.3 pct and 36.0 pct, respectively. The first break in the curve was observed in one experiment but not in another and was not caused by a phase change, because up to solution composition of 8.2 pct NiCl z-25.1 pct HCI, the tielines in figure 11 coverage on a NiCI2'6HzO composition. The crystals were large, green basal tablets characteristic of the hexahydrate. Babaeva and Archakova (5) performed equilibrium tests on this system at 20° C, and Balarew (6) performed equilibrium tests at 25° -C. Babaeva and Archakova observed no breakpoint, and their curve coincided with the curve in figure 10, in which a break was not obtained. Data of Balarew showed a breakpoint at about the same point as shown in figure 10. A metastable state must be occasionally formed in sparging and equilibrium tests.
The second break in the curve was noted at 8.2 pct NiCl z-25.1 pct HCI, whereas Babaeva and Archakova found the break at 11.6 pct NiCI2-21.2 pct HCI and Balarew found the break at between 20.42 pct NiCl z-13.71 pct HCI and 20.17 pct NiClz-14.46 pct HCI. The data of Babaeva and Archakova are in approximate agreement with figure 10, while the data of Balarew show a break at higher NiCl2 and lower HCI concentration, as would be expected for a higher temperature. Both groups of researchers attributed the break to the invariant point corresponding to the phase change from NiCl z "6HzO to NiCl 2 ·4HzO. The tieline data in figure 11 do not show a clear-cut transition. A change of phase is indicated at 8.2 pct NiClz-25.1 pct HCI, but the tieline
11
intersection is not precise and the location is intermediate to the hexahydrate and tetrahydrates. Microscopic examination showed that the crystals were green, basal tablets with a very large 2V and an index of refraction slightly less than 1.600 and verified that the crystals precipitated in 0 to 25.1 pct HCI concentration were the hexahydrate. The crystals produced at HCI concentrations greater than 25.1 pet were yellow-green, more platey than prismatic, but not well defined. The crystals had a 2V+ of 45 to 52 and an index of refraction of 1.600. Therefore, it is likely that the breakpoint at 25.1 pct HCI concentration represents the phase transition of NiCl z '6R20 to NiCl z ·4RzO.
The crystals obtained at 1.1 pct NiCl z-37.5 pct RCI concentrations were orthorhombic, elongated prisms, yellow, very small, and difficult to filter, and had indices of refraction slightly greater than 1.600. These crystals were probably dihydrate, even though the tieline data showed that the composition was tetrahydrate, and there were no obvious breaks in the solubility curve. Babaeva and Archakova did not observe a tetrahydrateto-dihydrate transition because the maximum RCI concentration was 30.7 pet. Balarew found a tetrahydrate-to-dihydrate phase change at 25° C, 4.0 pct NiCI2, and 29.6 pct HCI. The transition occurred at a HCI concentration of 6 to 8 pct less than noted in this work and is reasonable because of the 5° C temperature difference.
More research needs to be done on the NiCI2-RCI-HzO system to resolve experimental uncertainties and to reconcile contradictions in the literature. The aqueous solubility data in Linke-Seidell show
28.S 0 C 64.3° C NiC1 2 '6H20 + NiC1 2 04H20 + NiC1 2 0 2H 20,
r i
I
I,
Ii
12
while the data of Babaeva and Archakova for 80° C in Linke-Seidell show a solid phase throughout of NiCI2·4H20. The results of Foote (4) shown in Linke-Seidell that were supposed to be determined at 20° C were actually determined at 0° C and show phase changes from hexahydrate to tetrahydrate at 4.6 pct NICl2-26.0 pct HCI and from tetrahydrate to dihydrate at 1.4 pct NiCI 2-35.0 pct HCI. These are very close to the phase change compositions reported in this paper, even though there was a 20° C temperature difference.
Data for the system NiCI 2-HCI-H20 at 40° C were tabulated in table A-8 and plotted in figures 10 and 12. Solubility in aqueous solution was 43.3 pct, although the best fit to the data points up to 12.5 pct HCI concentration in figure 10 indicates a zero-HCI intercept at 42.4 pet NiCl z• No data for aqueous solubility at 40° C were given in Linke-Seidell, but when data for other temperatures were plotted, the solubility curve intersected the 40° C projection at 42.3 pct NiC12' Solubility at low HCl concentrations decreased at a slope of -1.5 pct NiCl 2 per percent HCI and was almost the same as the 20° and 60° C curves. There were no breaks in the solubility curve. Minimum NiC1 2 solubility was 1.0 pct and occurred at HCI saturation of 37.3 pct. The crystals were yellow-green, poorly defined, and more platey than prismatic, and had a 2V+ of 45 to 52 and an index of refraction of 1.600. The tieline data in figure 12 intersect at a point on the baseline corresponding to NiC1 2·4H20 and agree with aqueous solubility data in Linke-Seidell which show a tetrahydrate solid phase at 28.8° to 63.4° C.
KEY
o 40· C aqueous solubllity_ • Wet residue ~. • Theoretical Intercept 0-
~ .()
"-" \
FIGURE 12. - Tieline plot of the data for the NiCI 2-HCI.H 20 system at 40 0 C.
Data for the system NiC1 2-HCI-H20 at 60° C were tabulated in table A-9 and plotted in figures 10 and 13. Nickel chloride tetrahydrate salted out of saturated aqueous solution and gave an almost linear solubility curve with a slope of -1.5 pct NiC1 2 per percent HCI over the concentration range of ° to 18.6 pct HCI (44.4 to 18.6 pct NiCl z). Linke-Seidell gives aqueous saturation as 44.8 pct.
A slight break in the solubility curve in figure 10 and a substantial jump in the intersections in the tieline curve in figure 13 show that there is a phase change from NiC12·4H20 to NiClz·2H20 before the solubility curve decreases to a minimum NiCl z solubility of 3.8 pct at HCI saturation of 31.7 pct. The phase change from the tetrahydrate to the dihydrate would be expected from the solubility data in Linke-Seidell, which show that there is a phase change from NiCl2 ·4H20 to NiC12·2H20 at 64.3° C. The crystals changed from poorly defined yellow-green particles to very small, yellow, elongated prisms at the invariant point.
Two lines of evidence show that NiC1 2 crystals salted out of solution by HCI sparging are in equilibrium with NiCl 2 in solution. The solid diamonds in figure 10 represent solution concentrations of HCI and NiCl2 at 60° C for bottle tests representing equilibrium conditions. The data are very close to the curve constructed with data from sparging experiments. Data from five readings taken 12 to 24 h after cessation of sparging did not differ by more than 0.1 pct from data collected during sparging.
'" 60· C aqueous solubility
• Wet residue
• Theoretical intercept
4H20 2H20 -- H20, pet
\
FIGURE 13. - Tieline plot of the data for the NiCI 2"HCI.H 20 system at 60 0 C.
13
SUMMARY AND CONCLUSIONS
Comparison of published and Bureau data from equilibrium testing showed that HCI sparging experiments gave the same results as equilibrium tests for the CoCl z-, MnCl z-, and NiCI 2-HCl-HzO systems. The chlorides of Co, Mn, and Ni are very soluble in water and have solubilities of 33.9, 42.6, and 37.7 pct, respectively, at 20° C and of 48.3, 52.1, and 44.4 pct, respectively, at 60° C.
Many of the metal chlorides decrease in solubility and salt out of solution owing to the common ion effect when sparged with HCl gas. NiCl2 and MnC1 2 fall into this category, although NiCl 2 is much less soluble than MnCl 2 in solutions saturated with HCI. Some chlorides, such as FeCI 3 , form strong chloride complexes and become more soluble with HCI addition. CoCl2 is unusual in being very soluble in water and in concentrated HCI and minimally soluble at intermediate HCl concentrations.
The solubility decreases of cobalt, manganese, and nickel chlorides up to HCI concentrations of approximately 15 to 25 pct were linear and approximately parallel, with slopes of -1.3 to -1.5 pct metal chloride per percent HCl. Because of the almost identical behavior and high
solubilities, there is little likelihood that the chlorides of cobalt, manganese, or nickel can be separated from one another by sparging to HCI concentrations of less than 15 to 25 pet. At higher HCI concentrations, the solubilities of the three salts diverge owing to large differences in the strengths of the chloride complexes formed. In saturated HCI, the saturation compositions of CoCI 2, MnCl z , and NiC1 2 were as follows, in percent:
20° C 40° C 60° C
CoC12··········· 18.1 21.6 24.2 MaCI 2• •••••••••• 11.9 14.4 19.9 NiC1 2• •••••••••• 1.1 1.0 3.8
So it may be possible to separate cobalt and/or manganese from nickel in concentrated HCI. For instance, in the ternary system CoCI 2-HCI-H20 at 20° C, 18 pet CoCl 2 will be in solution at 32 pct HCI concentration, whereas in the NiC12-HCl-H20 system under comparable conditions, only 2.6 pct NiC1 2 will be in solution. Any possible separation scheme must overcome the handling problems inherent with the small elongated prism crystals common to the dihydrate form of the chlorides found at high temperature or in concentrated HCI.
REFERENCES
1. Linke, W. F. Solubilities, Inorganic and Metal-Organic Compounds. ACS, 4th ed., 1958, v. 1, 1487 pp., v. 2, 1914 pp. (This is a revision and continuation of the compilation originated by Atherton Seidell. )
2. Engel, R. Ann. Chim. Phys., v. 13, No.6, 1888, pp. 348-385.
3. Bassett, H., and Phase-Rule Study of the Colour Change. J. Chem. 1930, pp. 1784-1819.
H. Croucher. A Cobalt Chloride Soc. (London),
4. Foote, H. W. Equilibrium in the Systems Nickel Chloride, Cobalt Chloride, Cupric Chloride-Hydrochloric Acid-Water.
J. Am. Chem. Soc., v. 45, 1923, pp. 663-667.
5. Babaeva, A. V., and T. A. Archakova. (Equilibrium in the System Nickel Chloride-Hydrochloric Acid-Water.) Zh. Obschch. Khim., v. 5, 1935, pp. 21~-219; Chem. Abstr., v. 29, 1935, No. 5003 •
6. Balarew, C., D. Spassow, and B. Simeonowa. Untersuchung einiger Dreistoffsysteme vom Typ MeC12-HCI-H20 (Me =Ni 2+, Mn2+, Fe 2+) (Studies of Some Three-Component Systems of the Type MeC1 2-HCI-H20 (Me=Ni 2+, Mn2+, Fe 2+». Z. Anorg. und A1lg. Chem., v. 451, 1979, pp. 181-188 (Engl. sum.).
1':
14
7. Shanks, D. E., J. A. Eisele, and D. J. Bauer. Hydrogen Chloride Sparging Crystallization of Aluminum Chloride Hexahydrate. BuMines RI 8593, 1981, 15 pp.
8. Malquori, G. I sistemi AlC1 3-HClH20, KCl-HCl-H20 e KNOrHN03-H20 a 25°. (The Systems AlCl 3-HCI-H20 , KCl-HCl-HzO and KN03-HN03-H20 at 25°. III.) Atti. accad. Lincei., v. 5, 1927, pp. 576-578; Chem. Abstr., v. 21, 1927, No. 2414.
9. Seidel, W., and W. Fischer. Die Loslichkeit einiger Chloride und Doppelchloride in warriger Salzsaure als Grundlage von Trennungen (The Solubility of Some Chlorides and Double Chlorides in Hydrochloric Acid as a Basis of Separations). Z. Anorg. und Allg. Chem., v. 247, 1941, pp. 367-383.
10. Brown, R. R., G. E. Daut, R. V. Mrazek, and N. A. Gokcen. Solubility and Activity of Aluminum Chloride in Aqueous Hydrochloric Acid Solutions. BuMines RI 8379, 1979, 17 pp.
11. Schreinemakers, F. A. H. Graphiache Ableitungen aus den LosungsIsothermen eines Doppelsalzes und seiner Komponenten und mogliche Formen der Umwandlungskurve (Graphic Derivation of the Solubility Isotherm of Double Salts and Their Components and Possible Forms of the Transition Curve). Z. Phys. Chem., v. 11, 1893, p. 76.
12. Colton R., and J. H. Canterford. Halides of the Transition Elements. Halides of the First Row Transition Metals. Wiley-Interscience, 1969, 579 pp.
15
APPENDIX
TABLE A-I. - CoClz-HCI-H20 system at 20° C
Solution Wet residue Solution Wet residue HCI, pet CoCI 2, sp HCI, pet CoCl 2 , HCI, pet COCl z , sp HCI, pet CoCI 2,
pet gr pet pet gr pet 0.0 33.9 1.38 NA NA 20.4 9.5 1.17 NA NA 1.6 31.5 1.36 NA NA 22.0 9.4 1.17 NA NA 4.1 28.0 1.33 NA NA 23.5 10.6 1.20 .3 53.1 6.2 24.9 1.30 0.3 53.0 24.0 12.3 1.23 NA NA 7.7 22.9 1.28 NA NA 24.2 15.5 1.25 NA NA
10.0 20.0 1.26 NA NA 24.3 16.5 1.28 2.0 50.6 11.2 18.5 1.24 NA NA 24.3 16.5 1.28 5.9 49.3 12.8 16.6 1.23 NA NA 24.3 16.5 1.28 10.9 49.0 14.9 14.1 1.21 NA NA 24.4 16.4 1.27 NA NA 15.9 12.9 1.20 .5 52.5 26.1 15.8 1.28 NA NA 16.1 12.8 1.20 NA NA 27.9 16.0 1.29 8.7 54.4 17.5 11.4 1.19 NA NA 28.4 16.2 1.29 NA NA 18.6 10.5 1.18 NA NA 29.8 17.0 1. 31 7.7 54.9 19.7 9.8 1.17 NA NA 31.9 18.1 1.33 NA NA
NA Not analyzed.
TABLE A-2. - CoCI2-HCI-H20 system at 40° C
Solution Wet residue Solution Wet residue HCI, pet CoC1 2, sp HCI, pet CoClz, HCI, pet CoClz, sp HCI, pet CoClz,
pet gr pet pet gr pet 0.0 40.9 1.44 NA NA 16.6 25.1 1.32 NA NA 2.0 38.3 1.42 NA NA 17.1 24.4 1.31 NA NA 3.8 36.0 1.40 NA NA 17 .5 24.1 1.30 3.0 56.1 4.4 35.3 1.39 NA NA 17 .8 23.8 1.30 9.8 46.9 5.3 34.2 1.38 NA NA 20.0 21.4 1.27 NA NA 5.5 33.9 1.38 1.2 49.9 20.6 20.9 1.26 4.5 62.7 7.8 31.4 1.35 1.3 50.5 22.6 19.7 1.25 11.6 46.6 9.5 29.8 1.34 NA NA 24.1 19.6 1.26 5.9 61.4
11.9 28.1 1.31 1.3 49.4 26.5 20.3 1.29 NA NA 13.5 27.7 1.33 NA NA 26.9 20.7 1.29 7.2 58.4 14.3 27.8 1.35 2.1 49.7 27.8 21.2 1.31 4.4 64.3 14.5 27.5 1.35 NA NA 28.4 21.6 1.31 NA NA 15.1 26.8 1.34 3.6 54.1
NA Not analyzed.
16
TABLE A-3. - CoC12-RC1-H20 system at 60° C
Solution Wet residue Solution Wet residue HC1, pet CoC1 2 , sp HC1, pet CoC1 2 , HC1, pet CoC1 2 , sp HC1, pet CoC1 2,
pet gr pet pet gr pet 0.0 48.3 1.58 NA NA 14.4 30.0 1.36 4.3 61.0 1.6 46.0 1.55 NA NA 14.5 30.2 1.36 NA NA 3.6 43.5 1.52 NA NA 16.9 27.4 1.33 2.4 70.4 5.3 41.6 1.49 NA NA 17.3 27.3 1.33 NA NA 7.3 39.0 1.46 NA NA 19.6 25.2 1.31 1.9 71.7 7.4 1 39.0 NA NA NA 21.7 24.3 1.30 3.3 68.1 7.9 37.7 1.45 4.3 55.2 23.0 24.0 1.31 2.0 72.7 8.2 37.6 1.44 4.7 54.0 23.0 1 24.3 NA NA NA 9.2 36.2 1.43 2.3 66.8 23.9 24.2 1. 32 2.9 70.2 9.5 36.0 1.42 NA NA 23.9 24.2 1.32 2.1 73.5
10.5 34.5 1.41 3.4 62.7 24.0 24.3 1.32 2.5 70.1 11.7 33.5 1.39 NA NA 24.1 24.2 1.32 2.6 71.1 11.8 33.0 1.39 3.2 70.3 24.4 24.2 1.33 3.6 68.1 NA Not analyzed. 1Reading from solution after stirring at temperature for at least 12 h with no
sparging.
TABLE A-4. - MNC1 2-RC1-H20 system at 20° C
Solution Wet residue Solution Wet residue RCl, pet MnC1 2, sp HC1, pet MnC1 2, HC1, pet MnC1 2 , sp RC1, pet MnC1 2 ,
pet gr pet pet gr pet 0.0 42.6 1.47 NA NA 22.7 15.2 1.27 4.6 53.4
.8 42.0 1.46 NA NA 22.8 15.3 1. 27 NA NA 1.0 41.6 1.46 NA NA 24.2 15.5 1. 28 4.4 55.0 2.1 40.5 1.44 0.7 58.5 24.8 16.8 1.29 NA NA 2.7 38.6 1.44 NA NA 25.1 15.9 1.29 5.2 54.2 3.7 37.8 1.43 1.0 59.4 25.2 16.3 1.30 5.1 55.8 5.4 34.8 1.40 1.0 60.2 25.2 16.3 1.30 7.3 54.9 5.4 34.4 1.40 NA NA 25.3 16.3 1.30 11.2 49.8 7.7 31.8 1.37 1.4 59.4 26.3 15.3 1.29 NA NA 7.8 30.5 1.37 NA NA 26.5 14.8 1.29 12.0 48.8
10.0 28.8 1.34 1.8 58.6 28.0 13.9 1.29 11.3 51.2 10.9 26.4 1.33 NA NA 28.5 13.5 1.28 NA NA 12.6 24.4 1.31 NA NA 29.8 12.7 1.28 12.6 49.2 14.0 22.3 1.29 NA NA 30.9 12.1 1.28 13.5 48.3 14.6 21.9 1.29 NA NA 32.0 11.7 1.29 13.8 47.9 15.9 20.9 1.27 3.2 56.1 32.6 11.6 1.29 14.1 48.0 16.2 19.8 1.27 NA NA 33.0 11.8 1.29 NA NA 17.1 18.6 1.26 NA NA 33.0 11.6 1.29 8.9 58.2 18.1 17.9 1.26 NA NA 34.0 11.3 1.29 9.1 58.5 18.2 1 17 .8 1.26 NA NA 34.6 11.3 1.30 10.8 55.2 20.5 15.9 1.26 NA NA 34.6 11.3 1.30 10.4 56.2 20.9 16.1 1.26 4.0 55.6 34.7 11.7 1.30 NA NA 20.9 15.7 1.26 NA NA 35.0 11.9 1.30 NA NA NA Not analyzed. lReading from solution after stirring at temperature for at least 12 h with no
sparging.
17
Solution Wet residue Solution Wet residue RCI, pet MnCl 2 , sp RCI, pet MnCI 2, RCI, pet MnCI 2, sp RCI, pet MnC1 2 ,
pet gr pet pet gr pet 0.0 46.7 1.53 NA NA 15.9 28.1 1.36 NA NA 1.3 45.1 1.51 NA NA 16.1 27.5 1.36 NA NA 1.9 44.1 1.50 NA NA 16.5 26.2 1.36 7.0 55.7 2.2 43.6 1.50 NA NA 17.9 25.4 1.35 NA NA 4.4 40.9 1.47 NA NA 18.5 24.9 1.34 7.5 56.8 5.8 38.8 1.45 NA NA 19.4 23.9 1.34 NA NA 6.7 38.0 1.44 NA NA 20.3 22.6 1.33 8.2 55.3 8.3 36.2 1.42 2.0 57.7 21.1 21.8 1.33 NA NA 9.5 34.4 1.41 NA NA 22.9 19.6 1.32 NA NA 9.4 1 34.0 1.41 NA NA 24.2 18.9 1.31 9.3 54.0 9.9 34.3 1.41 2.2 57.3 26.1 16.8 1.30 NA NA
11.9 31.5 1.39 2.5 56.6 26.8 16.3 1.30 NA NA 13.3 30.4 1.38 2.1 58.5 27.9 15.6 1.30 10.9 52.6 13.4 30.1 1.38 NA NA 28.7 15.1 1.29 7.7 59.8 14.8 28.8 1.37 2.6 57.2 29.3 14.8 1.29 11.7 52.4 15.0 28.8 1.37 NA NA 30.6 14.6 1.29 12.5 51.5 15.5 28.3 1.36 NA NA 30.9 14.4 1.30 10.8 53.6
NA Not analyzed. lReading from solution after stirring at temperature for at least 12 h with no
sparging.
Solution Wet residue Solution Wet residue RCI, pet MnCI2, sp RCI, pet MnClz, RCI, pet MnCl z , sp RCI, pet MnCl z ,
pet gr pet pet gr pet 0.0 52.1 1.62 NA NA 12.8 34.0 1.43 NA NA
.5 51.5 1.61 NA NA 15.1 32.1 1.40 3.5 67.8 1.3 50.2 1.60 NA NA 16.9 29.0 1.38 NA NA 1.9 49.1 1.59 NA NA 18.4 25.8 1.36 NA NA 2.4 48.3 1.58 NA NA 18.9 27.0 1.35 2.6 72.6 2.9 47.8 1.57 NA NA 20.8 25.0 1.34 4.0 67.9 3.3 47.6 1.57 1.6 67.1 21.1 23.1 1.33 3.6 69.7 3.3 1 47.9 1.57 NA NA 22.2 22.9 1.32 NA NA 4.4 46.0 1.55 NA NA 23.6 21.2 1.32 3.6 68.1 5.3 44.1 1.54 NA NA 23.8 20.5 1.32 NA NA 6.5 43.1 1.52 2.5 66.1 24.5 19.7 1.32 NA NA 7.5 41.4 1.51 NA NA 24.6 20.1 1.32 NA NA 9.4 39.8 1.48 NA NA 24.6 21.2 1. 32 4.0 68.6
10.7 37.8 1.46 NA NA 24.6 21.0 1.32 4.1 70.0 11.1 36.2 1.46 NA NA 24.8 19.7 1.33 NA NA 12.5 35.2 1.44 3.2 67.5 25.5 19.9 1.33 NA NA
NA Not analyzed. lReading from solution after stirring at temperature for at least 12 h with no
sparging.
18
TABLE A-7. - NiC1 2-HCI-H20 system at 200 C
Solution Wet residue Solution Wet residue HCI t pet NiCI 2, sU HCI, pet NiCI 2, HCI, pet NiC1 2, sp HCI, pet NiCl 2 ,
pet gr pet pet gr pet 0.0 37.7 1.49 NA NA 22.4 10.3 1.21 NA NA
.8 36.7 1.48 NA NA 22.7 9.8 1.21 8.4 37.2 1.0 36.3 1.47 0.7 45.3 23.1 8.9 1.21 NA NA 1.7 36.3 1.46 NA NA 25.1 8.2 1.19 9.0 ,36.8 1.9 35.7 1.46 .9 45.2 27.3 4.6 1.18 NA NA 2.7 36.1 1.44 NA NA 27.6 4.9 1.18 15.8 28.3 2.7 1 36.1 NA NA NA 28.0 4.4 1.17 NA NA 3.0 34.2 1.44 1.6 43.1 29.6 3.2 1.17 NA NA 3.6 35.8 1.43 NA NA 30.0 3.2 1.16 NA NA 4.6 32.1 1.42 2.3 43.5 30.8 2.7 1.17 15.0 29.3 6.6 29.1 1.39 3.2 41.9 32.1 2.6 1.17 NA NA 7.2 28.1 1.38 NA NA 33.0 1.9 1.18 NA NA 9.1 26.1 1.35 4.9 38.9 33.2 2.2 1.18 NA NA 9.7 24.6 1.34 NA NA 34.3 1.7 1.18 8.7 44.9
12.3 21.6 1.30 NA NA 35.8 1.6 1.19 NA NA 14.0 19.6 1.28 6.5 37.7 36.0 1.3 1.19 NA NA 15.9 16.6 1.26 NA NA 37.1 .7 • 1.19 17.5 34.1 18.5 13.7 1.24 8.5 35.6 37.5 1.1
1
1•20 8.3 44.7
19.7 12.2 1.23 NA NA NA Not analyzed. lReading from solution after stirring at temperature for at least 12 h with no
sparging.
TABLE A-8. - NiC12-HCl-H20 system at 40 0 C
Solution Wet residue Solution Wet residue HCI, pet NiCI2, sp HCI, pet NiCI 2 , HCI, pet NiCI2, sp HCI, pet NiCI 2,
pet gr pet pet gr pet 0.0 43.3 1.53 NA NA 7.3 31.5 1.41 2.3 55.1
.4 42.2 1.52 NA NA 9.6 28.3 1.38 3.4 52.8
.6 41.8 1.52 NA NA 13.0 23.1 1.32 4.0 52.5
.9 41.1 1. 52 NA NA 16.6 18.5 1.29 5.2 51.6 1.2 40.7 1.51 NA NA 16.7 1 18.3 1.28 NA NA 1.4 40.4 1. 51 NA NA 21.2 12.7 1.25 6.2 49.9 1.6 40.1 1.51 NA NA 26.4 7.5 1.20 7.2 49.1 1.9 39.6 1.50 NA NA 29.0 5.5 1.19 NA NA 2.6 38.2 1.49 NA NA 30.1 5.0 1.18 7.9 49.4 5.0 35.3 1.45 1.9 53.6 30.4 4.7 1.18 NA NA 5.4 34.5 1.44 1.9 53.8 31.5 4.0 1.18 NA NA 7.2 32.0 1.41 2.6 53.7 37.3 1.0 1.17 NA NA NA Not analyzed. lReading from solution after stirring at temperature for at least 12 h with no
sparging.
19
TABLE A-9. - NiC12-HCl-H20 system at 60° C
Solution Wet residue Solution Wet residue HCl, pet NiC12, sp HCI, pet NiCI2, HCI, pet NiC1 2, sp HCl, pet NiC12,
pet gr pet pet gr pet 0.0 44.4 1.56 NA NA 22.0 13.8 1.24 9.4 48.7 1.2 43.1 1.55 0.0 53.2 21.8
' 13.9 1.26 NA NA
2.7 41.1 1.52 1.2 52.6 23.5 11.8 1.24 9.7 48.4 4.4 38.4 1.49 2.1 51.8 24.6 10.6 1.23 NA NA 6.1 35.8 1.47 2.7 51.2 25.3 9.8 1.23 10.4 47.5 8.3 32.6 1.43 3.3 51.1 26.7 8.2 1.21 NA NA 8.2 1 32.6 1.43 NA NA 26.4 I 8.3 1.21 NA NA 9.9 30.3 1.40 4.0 50.3 27.9 7.0 1.20 12.8 43.4
12.9 26.0 1.35 4.7 49.8 28.9 6.0 1.20 NA NA 13.1 26.0 1.35 4.9 49.6 28.9 6.1 1.20 12.3 45.5 15.5 22.5 1.32 5.6 48.5 29.5 5.5 1.19 12.5 43.8 15.6 1 22.5 1.32 NA NA 29.9 5.1 1.19 13.0 43.5 16.0 22.0 1.32 7.2 45.3 31.7 3.8 1.19 11.6 48.4 16.0 I 21.8 1.32 NA NA EQUILIBRIUM DATA FROM CLOSED-VESSEL 17.0 20.8 1.31 5.1 50.3 EXPERIMENTS 17.5 19.7 1.30 9.8 39.5 0.0 44.3 1.56 NA NA 17.5 20.2 1.30 6.3 47.2 1.6 42.1 1.54 0.9 49.6 18.2 19.0 1.29 4.9 51.1 7.4 33.8 1.44 3.9 46.9 18.6 18.3 1.29 5.7 49.5 11.2 28.0 1.38 3.6 51.6 18.6 18.5 1.29 5.6 51.1 18.4 18.6 1.29 5.1 58.2 19.7 16.6 1.28 NA NA 27.6 7.3 1.20 6.5 58.8
NA Not analyzed. 'Reading from solution after stirring at temperature for at least 12 h with no
sparging.
*U.S. GPO: 1985-505-019/20,010 INT.-BU.OF MINES,PGH.,PA. 27892